/* * fast fgets() replacement for log parsing * * Copyright 2000-2012 Willy Tarreau * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation, version 2.1 * exclusively. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public License * along with this library; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * * This function manages its own buffer and returns a pointer to that buffer * in order to avoid expensive memory copies. It also checks for line breaks * 32 or 64 bits at a time. It could be improved a lot using mmap() but we * would not be allowed to replace trailing \n with zeroes and we would be * limited to small log files on 32-bit machines. * */ #include #include #include #include #ifndef FGETS2_BUFSIZE #define FGETS2_BUFSIZE (256*1024) #endif /* memchr() is faster in glibc with SSE since commit 093ecf92998de2 */ #if defined(__x86_64__) && defined(__GLIBC__) && (__GLIBC__ > 2 || (__GLIBC__ == 2 && __GLIBC_MINOR__ >= 15)) #define USE_MEMCHR #endif /* return non-zero if the integer contains at least one zero byte */ static inline __attribute__((unused)) unsigned int has_zero32(unsigned int x) { unsigned int y; /* Principle: we want to perform 4 tests on one 32-bit int at once. For * this, we have to simulate an SIMD instruction which we don't have by * default. The principle is that a zero byte is the only one which * will cause a 1 to appear on the upper bit of a byte/word/etc... when * we subtract 1. So we can detect a zero byte if a one appears at any * of the bits 7, 15, 23 or 31 where it was not. It takes only one * instruction to test for the presence of any of these bits, but it is * still complex to check for their initial absence. Thus, we'll * proceed differently : we first save and clear only those bits, then * we check in the final result if one of them is present and was not. * The order of operations below is important to save registers and * tests. The result is used as a boolean, so the last test must apply * on the constant so that it can efficiently be inlined. */ #if defined(__i386__) /* gcc on x86 loves copying registers over and over even on code that * simple, so let's do it by hand to prevent it from doing so :-( */ asm("lea -0x01010101(%0),%1\n" "not %0\n" "and %1,%0\n" : "=a" (x), "=r"(y) : "0" (x) ); return x & 0x80808080; #else y = x - 0x01010101; /* generate a carry */ x = ~x & y; /* clear the bits that were already set */ return x & 0x80808080; #endif } /* return non-zero if the argument contains at least one zero byte. See principle above. */ static inline __attribute__((unused)) unsigned long long has_zero64(unsigned long long x) { unsigned long long y; y = x - 0x0101010101010101ULL; /* generate a carry */ y &= ~x; /* clear the bits that were already set */ return y & 0x8080808080808080ULL; } static inline __attribute__((unused)) unsigned long has_zero(unsigned long x) { return (sizeof(x) == 8) ? has_zero64(x) : has_zero32(x); } /* find a '\n' between and . Warning: may read slightly past . * If no '\n' is found, is returned. */ static char *find_lf(char *next, char *end) { #if defined USE_MEMCHR /* some recent libc use platform-specific optimizations to provide more * efficient byte search than below (eg: glibc 2.11 on x86_64). */ next = memchr(next, '\n', end - next); if (!next) next = end; #else if (sizeof(long) == 4) { /* 32-bit system */ /* this is a speed-up, we read 32 bits at once and check for an * LF character there. We stop if found then continue one at a * time. */ while (next < end && (((unsigned long)next) & 3) && *next != '\n') next++; /* Now next is multiple of 4 or equal to end. We know we can safely * read up to 32 bytes past end if needed because they're allocated. */ while (next < end) { if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; if (has_zero32(*(unsigned int *)next ^ 0x0A0A0A0A)) break; next += 4; } } else { /* 64-bit system */ /* this is a speed-up, we read 64 bits at once and check for an * LF character there. We stop if found then continue one at a * time. */ if (next <= end) { /* max 3 bytes tested here */ while ((((unsigned long)next) & 3) && *next != '\n') next++; /* maybe we have can skip 4 more bytes */ if ((((unsigned long)next) & 4) && !has_zero32(*(unsigned int *)next ^ 0x0A0A0A0AU)) next += 4; } /* now next is multiple of 8 or equal to end */ while (next <= (end-68)) { if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; if (has_zero64(*(unsigned long long *)next ^ 0x0A0A0A0A0A0A0A0AULL)) break; next += 8; } /* maybe we can skip 4 more bytes */ if (!has_zero32(*(unsigned int *)next ^ 0x0A0A0A0AU)) next += 4; } /* We finish if needed : if is below , it means we * found an LF in one of the 4 following bytes. */ while (next < end) { if (*next == '\n') break; next++; } #endif return next; } const char *fgets2(FILE *stream) { static char buffer[FGETS2_BUFSIZE + 68]; /* Note: +32 is enough on 32-bit systems */ static char *end = buffer; static char *line = buffer; char *next; int ret; next = line; while (1) { next = find_lf(next, end); if (next < end) { const char *start = line; *next = '\0'; line = next + 1; return start; } /* we found an incomplete line. First, let's move the * remaining part of the buffer to the beginning, then * try to complete the buffer with a new read. We can't * rely on anymore because it went past . */ if (line > buffer) { if (end != line) memmove(buffer, line, end - line); end = buffer + (end - line); next = end; line = buffer; } else { if (end == buffer + FGETS2_BUFSIZE) return NULL; } ret = read(fileno(stream), end, buffer + FGETS2_BUFSIZE - end); if (ret <= 0) { if (end == line) return NULL; *end = '\0'; end = line; /* ensure we stop next time */ return line; } end += ret; *end = '\n'; /* make parser stop ASAP */ /* search for '\n' again */ } } #ifdef BENCHMARK int main() { const char *p; unsigned int lines = 0; while ((p=fgets2(stdin))) lines++; printf("lines=%d\n", lines); return 0; } #endif